Dynamics of a photoexcited hydrated electron

M.S. Pshenichnikov; A. Baltuška; D.A. Wiersma

Dynamics of a photoexcited hydrated electron

M.S. Pshenichnikov, A. Baltuška, D.A. Wiersma

Zernike Institute for Advanced Materials

Research output: Chapter in Book/Report/Conference proceeding › Chapter › Academic

Abstract

Combining photon-echo and frequency-resolved pump-probe techniques with extremely short laser pulses that consist of only few optical cycles, we investigate the dynamics of the equilibrated hydrated electron. The pure dephasing time of the hydrated electron deduced from the photon-echo measurements is approximately 1.7 fs. The shape of the absorption spectrum is excellently described by an extended Lorentzian contour which spectral width is fully determined by the pure dephasing time. The experimental data is successfully described with a model in which the excited state lifetime is approximately 50 fs in water and approximately 70 fs in heavy water. The deuteration effect on the lifetime strongly suggests that OH(OD)-vibrational modes in the first solvation shell act as accepting modes for the energy relaxation.

Original language	English
Title of host publication	Few-Cycle Laser Pulse Generation and Its Applications
Editors	F.X. Kärtner
Place of Publication	BERLIN
Publisher	Springer
Pages	409-444
Number of pages	36
Edition	95
ISBN (Print)	9783540398493
Publication status	Published - 2004

Publication series

Name	TOPICS IN APPLIED PHYSICS
Publisher	SPRINGER-VERLAG BERLIN
Volume	95
ISSN (Print)	0303-4216

Keywords

OPTICAL-ABSORPTION SPECTRUM
FEMTOSECOND SOLVATION DYNAMICS
EXCITED STATE CHEMISTRY
PUMP-PROBE SPECTROSCOPY
SINGLE-CYCLE REGIME
MOLECULAR-DYNAMICS
LIQUID WATER
QUANTUM SIMULATION
EXCESS ELECTRONS
LASER-PULSES

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title = "Dynamics of a photoexcited hydrated electron",

abstract = "Combining photon-echo and frequency-resolved pump-probe techniques with extremely short laser pulses that consist of only few optical cycles, we investigate the dynamics of the equilibrated hydrated electron. The pure dephasing time of the hydrated electron deduced from the photon-echo measurements is approximately 1.7 fs. The shape of the absorption spectrum is excellently described by an extended Lorentzian contour which spectral width is fully determined by the pure dephasing time. The experimental data is successfully described with a model in which the excited state lifetime is approximately 50 fs in water and approximately 70 fs in heavy water. The deuteration effect on the lifetime strongly suggests that OH(OD)-vibrational modes in the first solvation shell act as accepting modes for the energy relaxation.",

keywords = "OPTICAL-ABSORPTION SPECTRUM, FEMTOSECOND SOLVATION DYNAMICS, EXCITED STATE CHEMISTRY, PUMP-PROBE SPECTROSCOPY, SINGLE-CYCLE REGIME, MOLECULAR-DYNAMICS, LIQUID WATER, QUANTUM SIMULATION, EXCESS ELECTRONS, LASER-PULSES",

author = "M.S. Pshenichnikov and A. Baltu{\v s}ka and D.A. Wiersma",

note = " Rights: Springer",

year = "2004",

language = "English",

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series = "TOPICS IN APPLIED PHYSICS",

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pages = "409--444",

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TY - CHAP

T1 - Dynamics of a photoexcited hydrated electron

AU - Pshenichnikov, M.S.

AU - Baltuška, A.

AU - Wiersma, D.A.

N1 - Rights: Springer

PY - 2004

Y1 - 2004

N2 - Combining photon-echo and frequency-resolved pump-probe techniques with extremely short laser pulses that consist of only few optical cycles, we investigate the dynamics of the equilibrated hydrated electron. The pure dephasing time of the hydrated electron deduced from the photon-echo measurements is approximately 1.7 fs. The shape of the absorption spectrum is excellently described by an extended Lorentzian contour which spectral width is fully determined by the pure dephasing time. The experimental data is successfully described with a model in which the excited state lifetime is approximately 50 fs in water and approximately 70 fs in heavy water. The deuteration effect on the lifetime strongly suggests that OH(OD)-vibrational modes in the first solvation shell act as accepting modes for the energy relaxation.

AB - Combining photon-echo and frequency-resolved pump-probe techniques with extremely short laser pulses that consist of only few optical cycles, we investigate the dynamics of the equilibrated hydrated electron. The pure dephasing time of the hydrated electron deduced from the photon-echo measurements is approximately 1.7 fs. The shape of the absorption spectrum is excellently described by an extended Lorentzian contour which spectral width is fully determined by the pure dephasing time. The experimental data is successfully described with a model in which the excited state lifetime is approximately 50 fs in water and approximately 70 fs in heavy water. The deuteration effect on the lifetime strongly suggests that OH(OD)-vibrational modes in the first solvation shell act as accepting modes for the energy relaxation.

KW - OPTICAL-ABSORPTION SPECTRUM

KW - FEMTOSECOND SOLVATION DYNAMICS

KW - EXCITED STATE CHEMISTRY

KW - PUMP-PROBE SPECTROSCOPY

KW - SINGLE-CYCLE REGIME

KW - MOLECULAR-DYNAMICS

KW - LIQUID WATER

KW - QUANTUM SIMULATION

KW - EXCESS ELECTRONS

KW - LASER-PULSES

M3 - Chapter

SN - 9783540398493

T3 - TOPICS IN APPLIED PHYSICS

SP - 409

EP - 444

BT - Few-Cycle Laser Pulse Generation and Its Applications

A2 - Kärtner, F.X.

PB - Springer

CY - BERLIN

ER -

Dynamics of a photoexcited hydrated electron

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